A semiconductor device includes a first insulating layer over a substrate, a first metal oxide layer over the first insulating layer, an oxide semiconductor layer over the first metal oxide layer, a second metal oxide layer over the oxide semiconductor layer, a gate insulating layer over the second metal oxide layer, a second insulating layer over the second metal oxide layer, and a gate electrode layer over the gate insulating layer. The gate insulating layer includes a region in contact with a side surface of the gate electrode layer. The second insulating layer includes a region in contact with the gate insulating layer. The oxide semiconductor layer includes first to third regions. The first region includes a region overlapping with the gate electrode layer. The second region, which is between the first and third regions, includes a region overlapping with the gate insulating layer or the second insulating layer. The second and third regions each include a region containing an element N (N is phosphorus, argon, or xenon).

A semiconductor device includes a first insulating layer over a substrate, a first metal oxide layer over the first insulating layer, an oxide semiconductor layer over the first metal oxide layer, a second metal oxide layer over the oxide semiconductor layer, a gate insulating layer over the second metal oxide layer, a second insulating layer over the second metal oxide layer, and a gate electrode layer over the gate insulating layer. The gate insulating layer includes a region in contact with a side surface of the gate electrode layer. The second insulating layer includes a region in contact with the gate insulating layer. The oxide semiconductor layer includes first to third regions. The first region includes a region overlapping with the gate electrode layer. The second region, which is between the first and third regions, includes a region overlapping with the gate insulating layer or the second insulating layer. The second and third regions each include a region containing an element N (N is phosphorus, argon, or xenon).

A lead frame strip includes a plurality of connected unit lead frames, each unit lead frame having a die paddle and a plurality of leads connected to a periphery of the unit lead frame. A semiconductor die is attached to each of the die paddles, the unit lead frames are covered with a molding compound after the semiconductor dies are attached to the die paddles, and a laser beam is directed at regions of the periphery of each unit lead frame where the leads are located thereby forming spaced apart cuts in the periphery of each unit lead frame. The spaced apart cuts sever the leads from the periphery of each unit lead frame and extend at least partially into the molding compound in the regions of the periphery where the leads are located so that the molding compound remains intact between the spaced apart cuts.

A method for transferring a layer of semiconductor by providing a donor substrate that includes a useful layer of a semiconductor material, a confinement structure that includes a confinement layer of a semiconductor material having a chemical composition that is different than that of the useful layer, and two protective layers of semiconductor material that are distinct from the confinement layer with the protective layers being arranged on both sides of the confinement layer; introducing ions into a donor substrate, bonding the donor substrate to a receiver substrate, subjecting the donor and receiver substrates to a heat treatment that provides an increase in temperature during which the confinement layer attracts the ions in order to concentrate them in the confinement layer, and detaching the donor substrate from the receiver substrate by breaking the confinement layer.

A method of bonding a device wafer to a carrier wafer includes disposing a first adhesive over a central portion of a carrier wafer, the first adhesive having a first glass transition temperature, disposing a second adhesive over a peripheral portion of the carrier wafer, the second adhesive having a second glass transition temperature greater than the first glass transition temperature, and bonding the first adhesive to an active front side of the device wafer and the second adhesive to a peripheral portion of the front side of the device wafer. Related assemblies may be used in such methods.

In a semiconductor device having a silicon carbide device, a technique capable of suppressing variation in a breakdown voltage and achieving reduction in an area of a termination structure is provided. In order to solve the above-described problem, in the present invention, in a semiconductor device having a silicon carbide device, a p-type first region and a p-type second region provided to be closer to an outer peripheral side than the first region are provided in a junction termination portion, a first concentration gradient is provided in the first region, and a second concentration gradient larger than the first concentration gradient is provided in the second region.

An apparatus for bonding semiconductor chips may comprise transfer rails configured to transfer substrates, loading members configured to load the substrates onto the transfer rails, unloading members configured to unload the substrates from the transfer rails, a first wafer supply unit configured to supply a first wafer including semiconductor chips, and/or a bonding unit configured to bond the semiconductor chips to the substrates. An apparatus for bonding semiconductor chips may comprise a transfer rail configured to transfer substrates, loading members configured to load the substrates onto the transfer rail, unloading members configured to unload the substrates from the transfer rail, a buffer member at a side of the transfer rail configured to temporarily receive the substrates loaded by the loading members, a first wafer supply unit configured to supply a first wafer including semiconductor chips, and/or a bonding unit configured to bond the semiconductor chips to the substrates.

A package process is provided. An adhesive layer is disposed on a carrier board and then plural first semiconductor devices are disposed on the adhesive layer. A first molding compound formed on the carrier board covers the sidewalls of the first semiconductor devices and fills the gaps between the first semiconductor devices so as to form a chip array board constructed by the first semiconductor devices and the first molding compound. Next, plural second semiconductor devices are flip-chip bonded to the first semiconductor devices respectively. Then, a second molding compound formed on the chip array board at least covers the sidewalls of the second semiconductor devices and fills the gaps between the second semiconductor devices. Subsequently, the chip array board is separated from the adhesive layer. Then, the first and the second molding compound are cut along the gaps between the second semiconductor devices.

Method for a controlled spalling utilizing vaporizable release layers. For example, a method comprises providing a base substrate, depositing a stressor layer and a vaporizable release layer on the base substrate, forming a flexible support layer on at least one of the stressor layer and the vaporizable release layer, spalling an upper portion of the base substrate, securing the spalled upper portion of the base substrate to a handle substrate, and vaporizing the vaporizable release layer.

A semiconductor device includes a first insulating layer over a substrate, a first metal oxide layer over the first insulating layer, an oxide semiconductor layer over the first metal oxide layer, a second metal oxide layer over the oxide semiconductor layer, a gate insulating layer over the second metal oxide layer, a second insulating layer over the second metal oxide layer, and a gate electrode layer over the gate insulating layer. The gate insulating layer includes a region in contact with a side surface of the gate electrode layer. The second insulating layer includes a region in contact with the gate insulating layer. The oxide semiconductor layer includes first to third regions. The first region includes a region overlapping with the gate electrode layer. The second region, which is between the first and third regions, includes a region overlapping with the gate insulating layer or the second insulating layer. The second and third regions each include a region containing an element N (N is phosphorus, argon, or xenon).